The study used TurboID-based proximity labeling coupled with mass spectrometry to map the Arabidopsis alternative splicing machinery centered on ACINUS, PININ, and SR45, identifying 298 high-confidence components and revealing that splicing is tightly linked to transcription and other RNA processing steps. Bioinformatic and genetic analyses, including O-glycosylation double mutants, demonstrated both conserved and plant‑specific regulatory networks and highlighted the role of sugar modifications in modulating splicing.

The study demonstrates that abscisic acid (ABA) accumulates in darkness to suppress cotyledon opening during seedling deetiolation, and that light exposure lifts this repression, enabling cotyledon aperture. Genome‑wide transcriptional and alternative‑splicing changes accompany this process, and the light‑dependent regulation requires the splicing factors RS40 and RS41, whose activity is repressed in the dark.